Abstract: Provided is a method of fabricating a magnetic axis-controlled structure. The method of fabricating a magnetic axis-controlled structure includes providing a composition including magnetic nanoparticles dispersed in a liquid medium, applying a magnetic field to the composition to align the magnetic nanoparticles along the magnetic field and form a magnetic axis, and solidifying the liquid medium to fix the magnetic axis.

Abstract: Provided are a solar cell apparatus and a method of manufacturing the same. More particularly, a high efficiency, inexpensive and large-area solar cell apparatus using a microlens, and a method of manufacturing the same are provided. The solar cell apparatus includes a plate on which a plurality of lenses are arranged on one surface, and a plurality of solar cells receiving light concentrated by the lenses.

Abstract: A light emitting device is provided. The light emitting device includes a p-type semiconductor, an n-type semiconductor, a semiconductor film connected between the p-type semiconductor and the n-type semiconductor, a first electrode disposed on the semiconductor film and configured to apply an electric field to the semiconductor film, and a second electrode disposed under the semiconductor film and configured to apply an additional electric field to the semiconductor film.

Abstract: A fluidic channel system is provided. The fluidic channel system includes a light projection apparatus, a fluidic channel, and a rail. The light projection apparatus provides light. A photocurable fluid, which is selectively cured by the light, flows inside the fluidic channel. A fine structure which is to be formed by curing the photocurable fluid moves along the rail.

Abstract: Provided is a light emitting diode (hereinafter, referred to as an LED) coating method, and more particularly, an LED coating method that can be used to coat a phosphor, a molding, etc., on an LED. The LED coating method includes (a) preparing a substrate and a plurality of LEDs arranged on the substrate; (b) applying a photoresist onto the substrate and the plurality of LEDs; and (c) selectively exposing the photoresist to light to form a first coating on surfaces of the plurality of LEDs. Here, the first coating is formed by curing the photoresist.

Abstract: The methods, systems 400 and apparatus disclosed herein concern metal 150 impregnated porous substrates 110, 210. Certain embodiments of the invention concern methods for producing metal-coated porous silicon substrates 110, 210 that exhibit greatly improved uniformity and depth of penetration of metal 150 deposition. The increased uniformity and depth allow improved and more reproducible Raman detection of analytes. In exemplary embodiments of the invention, the methods may comprise oxidation of porous silicon 110, immersion in a metal salt solution 130, drying and thermal decomposition of the metal salt 140 to form a metal deposit 150. In other exemplary embodiments of the invention, the methods may comprise microfluidic impregnation of porous silicon substrates 210 with one or more metal salt solutions 130. Other embodiments of the invention concern apparatus and/or systems 400 for Raman detection of analytes, comprising metal-coated porous silicon substrates 110, 210 prepared by the disclosed methods.

Abstract: The methods, systems 400 and apparatus disclosed herein concern metal 150 impregnated porous substrates 110, 210. Certain embodiments of the invention concern methods for producing metal-coated porous silicon substrates 110, 210 that exhibit greatly improved uniformity and depth of penetration of metal 150 deposition. The increased uniformity and depth allow improved and more reproducible Raman detection of analytes. In exemplary embodiments of the invention, the methods may comprise oxidation of porous silicon 110, immersion in a metal salt solution 130, drying and thermal decomposition of the metal salt 140 to form a metal deposit 150. In other exemplary embodiments of the invention, the methods may comprise microfluidic impregnation of porous silicon substrates 210 with one or more metal salt solutions 130. Other embodiments of the invention concern apparatus and/or systems 400 for Raman detection of analytes, comprising metal-coated porous silicon substrates 110, 210 prepared by the disclosed methods.

Abstract: The present invention relates to an optical identification tag, a reader, and a system, and more particularly, to an optical identification tag which transmits its identification information using energy input in an optical form, and an optical identification system and reader using the optical identification tag. The present invention provides an optical identification tag and an optical identification reader. The optical identification tag includes a solar cell for converting incident light into an electrical energy, a circuit for providing a transmitted electrical signal corresponding to identification information, and a light emitter for providing a transmitted optical signal corresponding to the transmitted electrical signal, and the optical identification reader provides the incident light to the optical identification tag, and receives the transmitted optical signal from the optical identification tag.

Abstract: An optofluidic lithography system including a membrane, a microfluidic channel, and a pneumatic chamber is provided. The membrane may be positioned between a pneumatic chamber and a microfluidic channel. The microfluidic channel may have a height corresponding to a displacement of the membrane and have a fluid flowing therein, the fluid being cured by light irradiated from the bottom to form a microstructure. The pneumatic chamber may induce the displacement of the membrane depending on an internal atmospheric pressure thereof.

Abstract: A method includes aligning nanotubes in a microfluidic channel including supplying nanotubes to the microfluidic channel; forming at least one interface in the channel; and applying a pressure to the microfluidic channel to control orientation of the nanotubes. A microfluidic device includes a silicon chip having a outer surface further including an upper surface and a lower surface; an upper wafer attached to the upper surface of the silicon chip; and a lower wafer attached to the lower surface of the silicon chip; wherein: the silicon chip, upper wafer, and lower wafer form a microfluidic channel; one or more nanotubes are aligned on the silicon chip according to the method; and the outer surface includes probe molecules.

Abstract: Techniques for fabricating nanostructures are provided. In one embodiment a method includes forming a multilayer stack including at least one pair of a structural layer and a sacrificial layer on a substrate, patterning the multilayer stack in order to fabricate a nanostructure, and releasing the nanostructure from the patterned multilayer stack.

Abstract: Disclosed are compositions and methods for self-assembling polymeric particles by using biological binders attached to subunits of a multi-sectioned polymeric particle.

Abstract: Disclosed is a method for sample detection by providing one or more samples to a microfluidic device including one or more microfluidic channels; and controlling one or more droplets in the channels to increase a likelihood of association between the one or more samples and one or more probes.

Abstract: Disclosed are membranes including a nanohole penetrating the membrane and two opposing faces. Method of making the membranes are also disclosed.

Abstract: A method of detecting deformation in a substrate includes detecting one or more changes in one or more emission characteristics of at least one pair of plasmon-coupled nanoparticles associated with a substrate, where the substrate includes at least one pair of plasmon-coupled nanoparticles. An apparatus for deformation detection includes a detection unit for detecting one or more changes in one or more emission characteristics of at least one pair of plasmon-coupled nanoparticles associated with a substrate.

Abstract: Disclosed are substrates for detecting one or more target molecules and methods for detecting molecules using surface plasmon resonance.

Abstract: Techniques for fabricating nanowire bundles are provided.

Abstract: Techniques for fabricating nanowires are disclosed.

Abstract: Nanostructure and techniques for fabricating nanostructures are provided. In one embodiment, nanostructures may be formed by providing a Silicon-on-Insulator (SOI) substrate, forming a pattern on the SOI substrate, disposing a conformal layer over the pattern, etching the conformal layer, except for a sidewall portion, removing the pattern, transferring the sidewall pattern to the silicon layer of the SOI substrate to form the nanostructure, and releasing the nanostructure.

Abstract: The present technology provides apparatuses for the detection of one or more target molecules. The apparatuses include a membrane having a nanochannel configured to allow passage of the target molecule, an electrical detection unit, and an optical detection unit. The apparatuses are capable of detecting the location of one or more target molecules, the time at which the molecules arrive at the location, as well as the identity of the molecules. Also disclosed are methods of making the apparatuses and methods of using the apparatuses to detect target molecules, including single biomolecules.